Total nutrient uptake by plants is

Total nutrient uptake by plants is a function of plant age, root size, and root uptake activity (Glass, 2003; Wang et al., 2003). It is thought that improving root systems will result in higher yields with smaller nutrient and water inputs (Gewin, 2010; Lynch, 2007). Previous studies have focused on root growth and development in maize during the vegetative period (Amos and Walters, 2006; Dwyer et al., 1996). Several studies have focused on the effects of N nutrition on the growth and development of maize root systems. During vegetative growth, increasing N supply can increase lateral root growth, resulting in increased total root length (Wang et al., 2005). Early studies by Anderson (1987) and Maizlish et al. (1980) indicated that increasing N supply resulted in increased maize root length in the field, but had little effect on root dry weight. Oikeh et al. (1999) suggested that maximum root growth of maize occurred under a moderate N supply, rather than under a low or high N supply.

In maize, 35 to 55% of the grain N originates from N taken up at the post-silking stage (Hirel et al., 2007). Therefore, the size and function of the root system during the grain-filling period may greatly affect GY formation and grain N accumulation in maize. At this stage, root size is balanced between the decay of old roots and the development of new roots (Gao et al., 1998; Li et al., 2010). As a result, the total root length usually decreases from silking to maturity (Gregory, 2006; Niu et al., 2010; Yan et al., 2011). At present, it is unknown whether increasing N supply can increase root growth, and consequently, delay the reduction in root length during the grain-filling period in maize. Burton et al. (2000) reported that in trees, an increased N supply increased root longevity. Similarly, increased levels of available N in soil were reported to decrease root mortality (Johnson et al., 2000; Majdi and Kangas, 1997; Ostertag, 2001). Ogawa et al. (2005) reported that root senescence was closely related to the supply of assimilates from the shoot. Consistent with this observation, reducing photosynthesis by covering leaves during the grain-filling stage significantly reduced the size of maize roots (Yan et al., 2011). In the present study, we evaluated the effects of different levels of N application on root morphology, the concentrations of nitrogenous compounds in xylem sap, N accumulation in plant tissues, and GY of maize in a field experiment. The specific objective was to determine whether a high N supply can delay root senescence during the grain-filling stage in field-grown maize.